2018
DOI: 10.1101/364265
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A smartphone-based tool for rapid, portable, and automated wide-field retinal imaging

Abstract: PurposeHigh-quality, wide-field retinal imaging is a valuable method to screen preventable, vision-threatening diseases of the retina. Smartphone-based retinal cameras hold promise for increasing access to retinal imaging, but variable image quality and restricted field of view can limit their utility. We developed and clinically tested a smartphone-based system that addresses these challenges with automation-assisted imaging. MethodsThe system was designed to improve smartphone retinal imaging by combining au… Show more

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Cited by 6 publications
(8 citation statements)
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“…Several other studies support the use of mydriatic smartphone-based fundus photography as a reliable and cost-effective option to expand screening for DR. 11,14 -16,18,29,30 The prospective CAMRA (Comparison Among Methods of Retinopathy Assessment) study of 300 patients compared smartphone fundus photography after dilation and nonmydriatic fundus photography against reference standard 7-field mydriatic fundus photography in their ability to detect and grade DR. 15 Tested in an outreach setting in India, detection of moderate NPDR or worse was comparable between mydriatic smartphone photography and nonmydriatic tabletop photography, with sensitivity of 59% (smartphone; 95% CI, 46%-72%) vs 54% (nonmydriatic; 95% CI, 40%-67%) and specificity of 100% (smartphone; 95% CI, 99%-100%) vs 99% (nonmydriatic; 95% CI, 98%-100%). Russo et al 14 prospectively compared mydriatic smartphone-based direct ophthalmoscopy to dilated slitlamp examination in the detection of DR in 120 patients with type 1 or type 2 diabetes and found exact agreement in 204 of 240 eyes (85%, κ = 0.78; CI, 0.71-0.84).…”
Section: Resultsmentioning
confidence: 99%
“…Several other studies support the use of mydriatic smartphone-based fundus photography as a reliable and cost-effective option to expand screening for DR. 11,14 -16,18,29,30 The prospective CAMRA (Comparison Among Methods of Retinopathy Assessment) study of 300 patients compared smartphone fundus photography after dilation and nonmydriatic fundus photography against reference standard 7-field mydriatic fundus photography in their ability to detect and grade DR. 15 Tested in an outreach setting in India, detection of moderate NPDR or worse was comparable between mydriatic smartphone photography and nonmydriatic tabletop photography, with sensitivity of 59% (smartphone; 95% CI, 46%-72%) vs 54% (nonmydriatic; 95% CI, 40%-67%) and specificity of 100% (smartphone; 95% CI, 99%-100%) vs 99% (nonmydriatic; 95% CI, 98%-100%). Russo et al 14 prospectively compared mydriatic smartphone-based direct ophthalmoscopy to dilated slitlamp examination in the detection of DR in 120 patients with type 1 or type 2 diabetes and found exact agreement in 204 of 240 eyes (85%, κ = 0.78; CI, 0.71-0.84).…”
Section: Resultsmentioning
confidence: 99%
“…Some studies have quantified usability improvements by measuring time for task completion, performing surveys, or conducting blinded image reviews. 11 , 129 , 133 Broader use of such assessments to substantiate improved usability of SBI systems should be encouraged. When possible, usability should be assessed in the intended clinical setting, but anatomical models and/or imaging phantoms can be good alternatives when clinical evaluation is infeasible.…”
Section: Discussionmentioning
confidence: 99%
“…As diagnostics are typically used for triage to treatment interventions, such applications more likely to be performed by medical personnel and in clinical settings rather than by individuals at home. Some of the primary in vivo diagnostic modalities proposed for SBI systems include white light imaging, 52 , 65 , 66 , 91 , 100 102 , 126 133 autofluorescence imaging, 17 , 65 , 66 , 71 , 100 multispectral/hyperspectral imaging, 52 , 64 , 88 endoscopy, 10 13 in vivo spectroscopy, 14 , 51 , 85 and in vivo microscopy. 14 16 , 62 , 134 For these modalities, the most frequent imaging sites are external tissues (dermis, facial, and retinal), externally accessible tissues (oral cavity, cervix, and ear), as well as some deeper tissues in the case of endoscopy (bladder, larynx, and esophagus).…”
Section: Context and Applicationsmentioning
confidence: 99%
“…The quick data transfer capability in smartphones can be utilized as an effective telemedicine tool to share and discuss the cases in remote places, e.g., screening for pediatric eye diseases such as ROP and diabetic retinopathy in children and adolescents. [ 29 ] Hazy vitreous, small pupil and vasculosa lentis could hamper good quality image acquisition. [ 26 ] There is a learning curve in using the smartphone camera to capture the images since it is based on inverted virtual images.…”
Section: Fundus Photography (Fp)mentioning
confidence: 99%